Vittorino da Feltre - Département d`Informatique de l`ENS
Transcription
Vittorino da Feltre - Département d`Informatique de l`ENS
MCCCXXIV (1324) Θεσσαλονίκη birth of Demetrios Kydones Demetrios Kydones (Δημήτριος Κυδώνης, 1324‐1397 in Crete) was a Byzantine theologian, translator, writer and influential statesman who served an unprecedented three terms as Imperial Prime Minister or Chancellor of the Byzantine Empire under three successive emperors: John VI Kantakouzenos, John V Palaiologos and Manuel II Palaiologos. As Imperial Premier, Kydones' effort during his second and third stints was to bring about a reconciliation of the Byzantine and Roman Churches, to cement a military alliance against the ever‐ encroaching Islam, a program that culminated in Emperor John V Palaiologos' reconciliation with Catholicism. Manuel Chrysoloras Manuel Chrysoloras (1355 –1415) was a pioneer in the introduction of Greek literature to Western Europe during the late middle ages. He was born in Constantinople to a distinguished family. Kydones was Crysolaras’ teacher. In 1390, he led an embassy sent to Venice by the emperor Manuel II Palaeologus to implore the aid of the Christian princes against the Muslim Turks. In 1396, the University of Florence, invited him to come and teach Greek grammar and literature, quoting Cicero: – "The verdict of our own Cicero confirms that we Romans either made wiser innovations than theirs by ourselves or improved on what we took from them, but of course, as he himself says elsewhere with reference to his own day: "Italy is invincible in war, Greece in culture." For our part, and we mean no offence, we firmly believe that both Greeks and Latins have always taken learning to a higher level by extending it to each other's literature." Manuel Chrysoloras Chrysoloras translated the works of Homer and Plato's Republic into Latin. His his Erotemata Civas Questiones which was the first basic Greek grammar in use in Western Europe, first published in 1484 and widely reprinted, and which enjoyed considerable success not only among his pupils in Florence, but also among later leading humanists, being immediately studied by Thomas Linacre at Oxford and by Desiderius Erasmus at Cambridge; and Epistolæ tres de comparatione veteris et novæ Romæ (Three Letters Comparing Ancient and Modern Rome). Many of his treatises on morals and ethics and other philosophical subjects came into print in the 17th and 18th centuries, because of their antiquarian interest. Manuel Chrysoloras Chrysoloras arrived to Florence in 1397. By the time there were many teachers of law, but no one had studied Greek in Italy for 700 years. Chrysoloras remained only a few years in Florence, from 1397 to 1400, teaching Greek, starting with the rudiments. He moved on to teach in Bologna and later in Venice and Rome. Among his pupils were numbered some of the foremost figures of the revival of Greek studies in Renaissance Italy. These alumni included Guarino da Verona. When Chrysoloras died in 1413, his death gave rise to commemorative essays of which Guarino da Verona made a collection in Chrysolorina. Guarino da Verona Guarino da Verona (1370‐1460) was an early figure in the Italian Renaissance. He was born in Verona and later studied Greek at Constantinople, during five years under Chrysoloras. When he set out to return home, he had with him two cases of precious Greek manuscripts which he had taken great pains to collect. It is said that the loss of one of these by shipwreck caused him such distress that his hair turned grey in a single night. On arriving back in Italy, he earned a living as a teacher of Greek, in Verona, Venice and Florence. In 1436, he became a professor of Greek at Ferrara through the patronage of Lionel, the marquis of Este. His method of instruction was renowned and attracted many students from Italy and the rest of Europe. Many of them, notably Vittorino da Feltre, afterwards became well‐known scholars. Guarino da Verona From 1438 on he interpreted for the Greeks at the councils of Ferrara and Florence. His principal works are translations of Strabo and of some of the Lives of Plutarch, a compendium of the Greek grammar of Chrysoloras, and a series of commentaries on Persius, Martial, the Satires of Juvenal, and on some of the writings of Aristotle and Cicero. Vittorino da Feltre Vittorino da Feltre (1378‐1446) was an Italian humanist and teacher, born in Feltre. His real name was Vittorino Ramboldini. He studied at Padua and later taught there, but after a few years he was invited by the marquis of Mantua to educate his children. At Mantua, Vittorino set up a school at which he taught the marquis's children and the children of other prominent families, together with many poor children, treating them all on an equal footing. He not only taught the humanistic subjects, but placed special emphasis on religious and physical education. Vittorino da Feltre He was one of the first modern educators to develop during the Renaissance. Many of his methods were novel, particularly in the close contacts between teacher and pupil as he had with Gasparino da Barzizza and in the adaptation of the teaching to the ability and needs of the child. He lived with students and befriended them in the first secular boarding school. Vittorino's school was well lit and built of better construction than other schools of the time. Vittorino also made school work more interesting, adding field trips to his curricula. He watched the health of his students very carefully, and generally elevated the status of teachers. Schools throughout Europe (especially England) copied Vittorino's model. Vittorino da Feltre Many of fifteenth century Italy's greatest scholars, including Guarino da Verona, sent their sons to study under Vittorino da Feltre. One of Vittorino's most noteworthy students was Theodorus Gaza. Theodorus Gaza Theodorus Gaza (1400–1475) was a Greek humanist and translator of Aristotle, one of the Greek scholars who were the leaders of the revival of learning in the 15th century (the Palaeologan Renaissance). He was born at Thessalonica. On the capture of his native city by the Turks in 1430 he fled to Italy. During a three years residence in Mantua he rapidly acquired a competent knowledge of Latin under the teaching of Vittorino da Feltre, supporting himself meanwhile by giving lessons in Greek, and by copying manuscripts of the ancient classics. In 1447 he became professor of Greek in the newly founded University of Ferrara, to which students in great numbers from all parts of Italy were soon attracted by his fame as a teacher. His students there included Rodolphus Agricola. Theodorus Gaza He had taken some part in the councils which were held in Siena (1423), Ferrara (1438), and Florence (1439), with the object of bringing about a reconciliation between the Greek and Latin Churches; and in 1450, at the invitation of Pope Nicholas V, he went to Rome, where he was for some years employed making Latin translations from Aristotle and other Greek authors. In Rome, he continued his teaching activities. After the death of Nicholas (1455), being unable to make a living at Rome, Gaza removed to Naples. Shortly afterwards he was appointed by Cardinal Bessarion to a benefice in Calabria, where the later years of his life were spent, and where he died about 1475. Theodorus Gaza His translations were superior, both in accuracy and style, to the versions in use before his time. He devoted particular attention to the translation and exposition of Aristotle's works on natural science. His Greek grammar (4 books), written in Greek, first printed at Venice in 1495, and partially translated by Erasmus in 1521, was for a long time the leading text‐book. His translations into Latin were very numerous. Rodolphus Agricola Rodolphus Agricola (1443–1485) was a pre‐Erasmian humanist of the northern Low Countries, famous for his supple Latin and one of the first north of the Alps to know Greek well. Agricola was a Hebrew scholar towards the end of his life, an educator, musician and builder of a church organ, a poet in Latin as well as the vernacular, a diplomat and a sportsman of sorts (boxing). He is best known today as the author of De inventione dialectica, as the father of northern European humanism and as a zealous anti‐scholastic in the late fifteenth century. De inventione dialectica was very influential in creating a proper place for logic in rhetorical studies, and was of great significance in the education of early humanists. It is a highly original, critical, and systematic treatment of all ideas and concepts related to dialectics. Rodolphus Agricola Agricola's De formando studio ‐ his long letter on a private educational program ‐ was printed as a small booklet and thus influenced pedagogical insights of the early sixteenth century. Erasmus greatly admired Agricola, eulogizing him in "Adagia"; Erasmus claimed him as a father/teacher figure and may have actually met him through his own schoolmaster Alexander Hegius, one of Agricola's students, at Hegius's school in Deventer. Erasmus made it his personal mission to ensure that several of Agricola's major works were printed posthumously. Agricola's 'De inventione dialectica' has a huge impact on Deaf community. He felt that a person born deaf can express himself by putting down his thoughts in writing. The book was not published until 100 years later. The statement that deaf people can be taught a language is one of the earliest positive statements about deafness on records. Alexander Hegius Alexander Hegius von Heek (1433–1498) was a German humanist, so called from his birthplace Heek in Westphalia. In 1474 he settled down at Deventer in Holland, where he either founded or succeeded to the headship of a school, which became famous for the number of its distinguished alumni. First and foremost of these was Erasmus; another famous alumnus of Hegius was Pope Adrian VI. His writings, consisting of short poems, philosophical essays, grammatical notes and letters, were published after his death. They display considerable knowledge of Latin, but less of Greek, on the value of which he strongly insisted. Alexander Hegius Hegius's chief claim to be remembered rests not upon his published works, but upon his services in the cause of humanism. He succeeded in abolishing the old‐fashioned medieval textbooks and methods of instruction, and led his pupils to the study of the classical authors themselves. His generosity in assisting poor students exhausted a considerable fortune, and at his death he left nothing but his books and clothes. Erasmus Desiderius Erasmus Roterodamus (1466–1536,) was a Dutch Renaissance humanist and a Catholic Christian theologian. Erasmus was a classical scholar who wrote in a "pure" Latin style and enjoyed the sobriquet "Prince of the Humanists." Using humanist techniques for working on texts, he prepared important new Latin and Greek editions of the New Testament. These raised questions that would be influential in the Protestant Reformation and Catholic Counter‐ Reformation. He also wrote The Praise of Folly, Handbook of a Christian Knight, On Civility in Children, and many other works. Erasmus Erasmus lived through the Reformation period and he consistently criticized some contemporary popular Christian beliefs. In relation to clerical abuses in the Church, Erasmus remained committed to reforming the Church from within. He also held to Catholic doctrines such as that of free will, which some Protestant Reformers rejected in favor of the doctrine of predestination. His middle road disappointed and even angered many Protestants, such as Martin Luther, as well as conservative Catholics. Erasmus One of Erasmus’ best known works is Adagia, a collection of 4658 Greek and Latin adages. Many of which are common today! Make haste slowly One step at a time To be in the same boat To lead one by the nose A rare bird Even a child can see it To walk on tiptoe One to one Out of tune A point in time To call a spade a spade Hatched from the same egg Up to both ears (Up to his eyeballs) As though in a mirror Think before you start What's done cannot be undone We cannot all do everything Many hands make light work A living corpse Where there's life, there's hope To cut to the quick Time reveals all things Golden handcuffs Crocodile tears To show the middle finger To walk the tightrope We all live in a yellow submarine, yellow submarine Cause we are living in a material world and I’m a material girl To dangle the bait To swallow the hook The bowels of the earth From heaven to earth Erasmus One of Erasmus’ best known works is Adagia, a collection of 4658 Greek and Latin adages. Many of which are common today! Make haste slowly One step at a time To be in the same boat To lead one by the nose A rare bird Even a child can see it To walk on tiptoe One to one Out of tune A point in time To call a spade a spade Hatched from the same egg Up to both ears (Up to his eyeballs) As though in a mirror Think before you start What's done cannot be undone We cannot all do everything Many hands make light work A living corpse Where there's life, there's hope To cut to the quick Time reveals all things Golden handcuffs Crocodile tears To show the middle finger To walk the tightrope We all live in a yellow submarine, yellow submarine Cause we are living in a material world and I’m a material girl To dangle the bait To swallow the hook The bowels of the earth From heaven to earth : : •The dog is worthy of his dinner •To weigh anchor •To grind one's teeth •Nowhere near the mark •Complete the circle •In the land of the blind, the one‐eyed man is king •No sooner said than done •A necessary evil •There's many a slip 'twixt cup and lip •To squeeze water out of a stone •To leave no stone unturned •Let the cobbler stick to his last (Stick to your knitting) •God helps those who help themselves •The grass is greener over the fence •The cart before the horse •Dog in the manger •One swallow doesn't make a summer •His heart was in his boots •To sleep on it •To break the ice •Ship‐shape •To die of laughing •To have an iron in the fire •To look a gift horse in the mouth •Neither fish nor flesh : : Jacob Milich Jacob Milich (1501–1559) was a disciple of Erasmus, German physician, mathematician, and astronomer. He was born in Freiburg im Breisgau, where he received his education starting in 1513. He taught at Wittenberg, where he became a professor of mathematics. His most important student there was Erasmus Reinhold. He became Dean of the Wittenberg university's philosophical and medical branches, then served as Rector of the school on several occasions. The crater Milichius on the Moon is named after him. Erasmus Reinhold Erasmus Reinhold (1511 –1553) was a German astronomer and mathematician, considered to be the most influential astronomical pedagogue of his generation. He was born and died in Saalfeld, Germany. He was educated at the University of Wittenberg, where he became dean and later rector. In 1536 he was appointed professor of higher mathematics. In contrast to the limited modern definition, "mathematics" at the time also included applied mathematics, especially astronomy. Reinhold catalogued a large number of stars. Duke Albert of Brandenburg Prussia supported Reinhold and financed the printing of Reinhold's Prutenicae Tabulae or Prussian Tables. These astronomical tables helped to disseminate calculation methods of Copernicus throughout the Empire. Erasmus Reinhold Both Reinholds's Prutenic Tables and Copernicus' studies were the foundation for the Calendar Reform by Pope Gregory XIII in 1582. However, Reinhold (like other astronomers before Kepler and Galileo) translated Copernicus' mathematical methods back into a geocentric system, rejecting heliocentric cosmology on physical and theological grounds. Reinhold tutored many disciples amongst whom was Valentin Naboth. Valentin Naboth Valentin Naboth was born in Niederlausitz to a Jewish family. In 1544, Valentin immatriculated at the University of Wittenberg when Erasmus Reinhold taught there. In 1550 he transferred to the University of Erfurt. From 1553 Naboth taught mathematics at the University of Cologne. When he arrived at Cologne he began teaching mathematics as Privatdozent, since that discipline was not included in the university curriculum. He made such an impression that he was offered a University position, remunerated for his private lessons, and made ordinary professor. Dutch mathematician Rudolph Snellius was one of his students in Cologne. Valentin Naboth Naboth was the author of a general textbook on astrology Enarratio elementorum astrologiae. Renowned for calculating the mean annual motion of the Sun, his writings are chiefly devoted to commenting upon Ptolemy and the Arabian astrologers. Naboth teaches the calculation of the movement of the planets according to the Prutenic Tables of Erasmus Reinhold. He advocated a measure of time, by which 0°59'09" (the mean daily motion of the Sun in longitude) is equated to 1 year of life in calculating primary directions. This was a refinement of Ptolemy’s value of exactly 1 degree per year. This book was banned by the Roman Catholic Church. Ducunt volentem fata, nolentem trahunt! In March 1564 Naboth resigned from his position at the University of Cologne. He traveled to Italy, eventually settling in Padua. There Naboth came to a bad end. He was living in Padua, Italy, when he deduced from his own horoscope that he was about to enter a period of personal danger, so he stockpiled an adequate supply of food and drink, closed his blinds, and locked his doors and windows, intending to stay in hiding until the period of danger had passed. Unfortunately, some thieves, seeing the house closed and the blinds drawn, decided that the resident was absent. They therefore broke into what they thought was an empty house, and, finding Naboth there, murdered him to conceal their identities. Thus he did not escape the fate predicted… by his own astrological calculations. Rudolph Snel van Royen Rudolph Snel (latinized as Snellius, 1546‐1613) was a Dutch linguist and mathematician. Born to a wealthy family, Rudolf Snel grew up in Utrecht. At maturity he left to study at the University of Cologne (under Valentin Naboth) and the University of Heidelberg. He soon received a teaching position at the University of Marburg. In 1578, he was offered, and accepted, a position as professor of Hebrew and mathematics at the University of Leiden, where he taught until his death in 1613. Snel was an influence on some of the leading political and intellectual forces of the Dutch Golden Age. Finally, not the least of Snel’s influence was cast upon his son, Willebrord Snellius, who would become the distinguished astronomer and mathematician. Willebrord Snellius Willebrord Snellius (1580–1626, Leiden) was a Dutch astronomer and mathematician. His name is attached to the law of refraction of light (it is now known that this law was discovered by Ibn Sahl in 984). In 1613 he succeeded his father as professor of mathematics at the University of Leiden. In 1615 he planned a new method of finding the radius of the earth, by determining the distance of one point on its surface from the parallel of latitude of another, by means of triangulation. This work describes the method and gives as the result of his operations between Alkmaar and Bergen op Zoom which he measured to be equal to 107.395 km. The actual distance is approximately 111 km. Snellius also produced a new method for calculating π, the first such improvement since ancient times. He rediscovered the law of refraction in 1621. The lunar crater Snellius is named after Willebrord Snellius. Snell’s law Snell’s Crater Jacob van Gool Jacob Golius (1596‐1667), was a Dutch Orientalist and mathematician. Golius came to the University of Leiden in 1612 to study mathematics (under Snel Jr.). In 1618 he registered again to study Arabic and other Eastern languages. In 1622 he accompanied the Dutch embassy to Morocco. On his return he got a professorship. In the following year he set out on a Syrian and Arabian tour from which he did not return until 1629. The remainder of his life was spent at Leiden where he held the chair of mathematics as well as that of Arabic. His most important work is the Lexicon Arabico‐Latinum (1653) which was only superseded in 1837. Among his earlier publications may be mentioned editions of various Arabic texts. After his death, there was found among his papers a Dictionarium Persico‐Latinum which was published in 1669. Golius also edited, translated and annotated the astronomical treatise of Alfragan in 1669. van Gool’s most famous student is René Descartes However, we will continue with another, less brilliant, yet famous, student of Gool: Franciscus van Schooten Franciscus van Schooten Franciscus van Schooten (1615–1660) was a Dutch mathematician known for popularizing the analytic geometry of René Descartes. Schooten read Descartes' Géométrie (an appendix to his Discours de la méthode) while it was still unpublished. Finding it hard to understand, he went to France to study the works of other important mathematicians of his time, such as François Viète and Pierre de Fermat. When he returned to his home in Leiden in 1646, he became a professor having Christiaan Huygens as a student. Schooten's 1649 Latin translation and commentary of Descartes' Géométrie made the work comprehensible to the broader mathematical community, and thus was responsible for the spread of analytic geometry to the world. Over the next decade he expanded the commentaries to two volumes, published in 1659 and 1661. This edition and its extensive commentaries was far more influential than the 1649 edition. It was this edition that Gottfried Leibniz and Isaac Newton knew. Franciscus van Schooten Schooten was one of the first to suggest, in exercises published in 1657, that these ideas be extended to three‐dimensional space. His efforts made Leiden the centre of the mathematical community for a short period in the middle of the seventeenth century. Christiaan Huygens Christiaan Huygens (1629–1695) was a prominent Dutch mathematician, astronomer, physicist, horologist, and writer of early science fiction. His work included early telescopic studies elucidating the nature of the rings of Saturn and the discovery of its moon Titan, investigations and inventions related to time keeping and the pendulum clock, and studies of both optics and the centrifugal force. Huygens achieved note for his argument that light consists of waves, now known as the Huygens–Fresnel principle, which became instrumental in the understanding of wave‐particle duality. He generally receives credit for his discovery of the centrifugal force, the laws for collision of bodies, for his role in the development of modern calculus and his original observations on sound perception. Huygens is seen as the first theoretical physicist as he was the first to use formulae in physics. Named After Christiaan Huygens • The Huygens probe: The lander for the Saturnian moon Titan, part of the Cassini‐Huygens Mission to Saturn • Asteroid 2801 Huygens • A crater on Mars • Mons Huygens, a mountain on the Moon • Huygens Software, a microscope image processing package. • Achromatic two element eyepiece designed by him. • The Huygens–Fresnel principle, a simple model to understand disturbances in wave propagation. • Huygens wavelets, the fundamental mathematical basis for scalar diffraction theory Named After Christiaan Huygens • W.I.S.V. Christiaan Huygens: Dutch study guild for the studies Mathematics and Computer Science at the Delft University of Technology • Huygens Laboratory: Home of the Physics department at Leiden University, The Netherlands • Huygens Supercomputer: National Supercomputer facility of The Netherlands, located at SARA in Amsterdam • The Huygens‐building in Noordwijk, The Netherlands, first building on the Space Business park opposite Estec (ESA) • The Huygens‐building at the Radboud University, Nijmegen, The Netherlands. One of the major buildings of the science department at the university of Nijmegen. • etc… Huygens: Mechanics Huygens formulated what is now known as the second law of motion of Isaac Newton in a quadratic form. Newton reformulated and generalized that law. In 1659 Huygens derived the now well‐known formula for the centrifugal force, exerted by an object describing a circular motion, for instance on the string to which it is attached, in modern notation: with m the mass of the object, v the velocity and r the radius. Furthermore, Huygens concluded that Descartes' laws for the elastic collision of two bodies must be wrong and formulated the correct laws. Huygens: Wave Theory and Optics Huygens is remembered especially for his wave theory of light, expounded in his Traité de la lumière (see also Huygens‐Fresnel principle). The later theory of light by Isaac Newton in his Opticks proposed a different explanation for reflection, refraction and interference of light assuming the existence of light particles. The interference experiments of Thomas Young vindicated Huygens' wave theory in 1801, as the results could no longer be explained with light particles. Huygens experimented with double refraction in Icelandic crystal (calcite) and explained it with his wavetheory and polarised light. Huygens: Clocks He also worked on the construction of accurate clocks, suitable for naval navigation. In 1658 he published a book on this topic called Horologium. His invention of the pendulum clock, patented in 1657, was a breakthrough in timekeeping. Huygens discovered that the cycloid was an isochronous curve and, applied to pendulum clocks in the form of cycloidal cheeks guiding a flexible pendulum suspension, would ensure a regular (i.e isochronous) swing of the pendulum irrespective of its amplitude, i.e. irrespective of how it moved side to side. The mathematical and practical details of this finding were published in "Horologium Oscillatorium" of 1673. Huygens: Clocks Huygens was the first to derive the formula for the period of the mathematical pendulum (with massless rod or cable), in modern notation: with T the period, l the length of the pendulum and g the gravitational acceleration. In 1675, Christiaan Huygens patented a pocket watch. Huygens: Astronomy In 1655, Huygens proposed that Saturn was surrounded by a solid ring, "a thin, flat ring, nowhere touching, and inclined to the ecliptic." Using a 50 power refracting telescope that he designed himself, Huygens also discovered the first of Saturn's moons, Titan. In the same year he observed and sketched the Orion Nebula. His drawing, the first such known of the Orion nebula, was published in Systema Saturnium in 1659. Using his modern telescope he succeeded in subdividing the nebula into different stars. He also discovered several interstellar nebulae and some double stars. In 1661, he observed planet Mercury transit over the Sun. Gottfried Wilhelm Leibniz It is impossible to present Leibniz’ (1646‐1716) contribution to humanity without devoting to it at least an entire workshop. He is remembered for work in infinitesimal calculus, calculus, a new formula for π, Leibniz’ harmonic triangle, Leibniz formula for determinants, Leibniz integral rule, Leibniz differential, Notation for differentiation, Differential calculus, Proof of Fermat's little theorem and Kinetic energy. Other contributions, in the fields of humanity or philosophy, are less known to the mathematical community. These nonetheless include: Monadology, Theodicy, Optimism, Principle of sufficient reason, Diagrammatic reasoning, Principle of Sufficient Reason • For every entity x, if x exists, then there is a sufficient explanation why x exists. • For every event e, if e occurs, then there is a sufficient explanation why e occurs. • For every proposition p, if p is true, then there is a sufficient explanation why p is true. Diagrammatic reasoning Reasoning can be symbolized as icons visually related using lines to represent relations and combinations of basic components (the ancestor of today’s flowchart). Theodicity (θεός + δίκη) Why evil happens? Leibniz thought that the evil in the world does not conflict with the goodness of God, and that notwithstanding its many evils, the world we know is the best of all possible worlds. Leibniz wrote his Théodicée as a criticism of Pierre Bayle's Dictionnaire Historique et Critique, that argued that the sufferings experienced in this earthly life prove that God could not be good and omnipotent Gottfried Wilhelm Leibniz Jacob Bernoulli Jacob Bernouilli (1654‐1705) was a disciple of Leibniz. He studied theology and entered the ministry. But contrary to the desires of his parents, he also studied mathematics and astronomy. He traveled throughout Europe from 1676 to 1682, learning about the latest discoveries in mathematics and the sciences. He published papers on transcendental curves (1696) and isoperimetry (1700, 1701). In 1690, Jacob became the first person to develop the technique for solving separable differential equations. Jacob Bernoulli Upon returning to Basel in 1682, he founded a school for mathematics and the sciences. He was appointed professor of mathematics at the University of Basel in 1687, remaining in this position for the rest of his life. He is the author as the law of large numbers. The terms Bernoulli trial and Bernoulli numbers result from this work. The lunar crater Bernoulli is also named after him jointly with his brother Johann. Bernoulli chose a figure of a logarithmic spiral and the motto Eadem mutata resurgo for his gravestone; the spiral executed by the stonemasons was, however, an Archimedean spiral. Jacob had five daughters and three sons. Jacob Bernoulli Johann Bernoulli Johann (1667–1748) was the brother of Jacob. Johann began studying medicine but did not enjoy it and began studying mathematics on the side with Jacob. The Bernoulli brothers worked together spending much of their time studying the newly discovered calculus. After graduating from Basel University Johann Bernoulli moved to teach differential equations and in 1694, became a professor of mathematics at the University of Groningen. As a student of Leibniz’s calculus, Johann Bernoulli sided with him in 1713 in the Newton–Leibniz debate over who deserved credit for the discovery of calculus. Johann Bernoulli defended Leibniz by showing that he had solved certain problems with his methods that Newton had failed to solve. Johann Bernoulli In 1691 Johann solved the problem of the catenary presented by Jakob. In 1696 Johann proposed the problem of the brachistochrone, despite already having solved the problem himself. Within two years he received five answers, one of which was from his older brother, Jakob. Johann Bernoulli Johann Bernoulli Johann was hired by Guillaume François Antoine de L'Hôpital to tutor him in mathematics. Bernoulli and L'Hôpital signed a contract which gave L'Hôpital the right to use Bernoulli’s discoveries as he pleased. L'Hôpital authored the first textbook on calculus, which mainly consisted of the work of Bernoulli, including what is now known as L'Hôpital's rule. Johann educated the great mathematician Leonhard Euler in his youth Leonhard Paul Euler Leonhard Paul Euler (1707–1783) was a pioneering Swiss mathematician and physicist who spent most of his life in Russia and Germany. Euler made important discoveries in fields as diverse as calculus and graph theory. He also introduced much of the modern mathematical terminology and notation, particularly for mathematical analysis, such as the notion of a mathematical function. He is also renowned for his work in mechanics, fluid dynamics, optics, and astronomy. Euler is considered to be the preeminent mathematician of the 18th century and one of the greatest of all times. He is also one of the most prolific; his collected works fill 60–80 quarto volumes. The city of Kaliningrad (Russia) was set on both sides of the Pregel River, and included two large islands which were connected to each other and the mainland by seven bridges. The problem was to find a walk through the city that would cross each bridge once and only once. The islands could not be reached by any route other than the bridges, and every bridge must have been crossed completely every time (one could not walk halfway onto the bridge and then turn around to come at it from another side). V − E + F = 2 relates the number of vertices, edges, and faces of a convex polyhedron The asteroid 2002 Euler was named in his honor. He is also commemorated by the Lutheran Church on their Calendar of Saints on 24 May ‐ he was a devout Christian (and believer in biblical inerrancy) who wrote apologetics and argued forcefully against the prominent atheists of his time. Joseph Lagrange Joseph‐Louis Lagrange, born Giuseppe Lodovico Lagrangia (1736– 1813) was an Italian‐born mathematician and astronomer, who lived most of his life in Prussia and France, making significant contributions to all fields of analysis, to number theory, and to classical and celestial mechanics. On the recommendation of Euler and D'Alembert, in 1766 Lagrange succeeded Euler as the director of mathematics at the Prussian Academy of Sciences in Berlin, where he stayed for over twenty years, producing a large body of work and winning several prizes of the French Academy of Sciences. Lagrange's treatise on analytical mechanics (Mécanique Analytique, 1888), written in Berlin and first published in 1788, offered the most comprehensive treatment of classical mechanics since Newton and formed a basis for the development of mathematical physics in the nineteenth century. French or Italian? Born Giuseppe Lodovico Lagrangia in Turin of Italian parents, Lagrange had French ancestors on his father's side. In 1787 he became a member of the French Academy, and he remained in France until the end of his life. Therefore, Lagrange is alternatively considered a French and an Italian scientist. Lagrange survived the French Revolution and became the first professor of analysis at the École Polytechnique upon its opening in 1794. Napoleon named Lagrange to the Legion of Honour and made him a Count of the Empire in 1808. He is buried in the Panthéon. Some of Lagrange’s Results Lagrange (1766–1769) was the first to prove that Pell's equation x2 − ny2 = 1 has a nontrivial solution in the integers for any non‐ square natural number n. He proved the theorem, stated by Bachet without justification, that every positive integer is the sum of four squares, 1770. He proved Wilson's theorem that if n is a prime, then (n − 1)! + 1 is always a multiple of n, 1771. His papers of 1773, 1775, and 1777 gave demonstrations of several results enunciated by Fermat, and not previously proved. His Recherches d'Arithmétique of 1775 developed a general theory of binary quadratic forms to handle the general problem of when an integer is representable by the form ax2 + by2 + cxy. Joseph Lagrange Siméon Poisson Siméon Poisson entered the École Polytechnique in 1798. In 1800, less than two years after his entry, he published two memoirs, one on Étienne Bézout's method of elimination, the other on the number of integrals of a finite difference equation. The latter was examined by Legendre, who recommended that it should be published in the Recueil des savants étrangers, an unprecedented honor for a youth of eighteen. This success at once procured entry for Poisson into scientific circles. Lagrange, who lectured at the École Polytechnique, recognized Poisson’s talent, and also became his friend. Laplace, in whose footsteps Poisson followed, regarded him almost as his son. Poisson was made deputy professor in 1802, and, in 1806 full professor succeeding Fourier. In 1808 he became astronomer to the Bureau des Longitudes; and professor of rational mechanics in 1809. Siméon Poisson He became a member of the Institute in 1812, examiner at the military school of Saint‐Cyr in 1815, graduation examiner at the École Polytechnique in 1816, councillor of the university in 1820, and geometer to the Bureau des Longitudes succeeding Laplace in 1827. His father, whose early experiences had led him to hate aristocrats, bred him in the creed of the First Republic. Throughout the Revolution, the Empire, and the following restoration, Poisson was not interested in politics, concentrating on mathematics. He was appointed to the dignity of baron in 1821; but he neither took out the diploma or used the title. Siméon Poisson The revolution of July 1830 threatened him with the loss of all his honors; but this disgrace to the government of Louis‐ Philippe was adroitly averted by François Arago, who, while his "revocation" was being plotted by the council of ministers, procured him an invitation to dine at the Palais Royal, where he was openly and effusively received by the citizen king, who "remembered" him. After this, of course, his degradation was impossible, and seven years later he was made a peer of France, not for political reasons, but as a representative of French science. Notwithstanding his many official duties, he found time to publish more than three hundred works, several of them extensive treatises. Siméon Poisson’s Works Memoirs on the theory of electricity and magnetism, which virtually created a new branch of mathematical physics. Next in importance stand the memoirs on celestial mechanics. The most important of these are his memoirs Sur les inégalités séculaires des moyens mouvements des planètes, Sur la variation des constantes arbitraires dans les questions de mécanique, (1809); Sur la libration de la lune, (1821), and Sur le mouvement de la terre autour de son centre de gravité (1827). Poisson Distribution In probability the Poisson distribution is a discrete probability distribution that expresses the probability of a number of events occurring in a fixed period of time if these events occur with a known average rate and independently of the time since the last event. The Poisson distribution can also be used for the number of events in other specified intervals such as distance, area or volume. The distribution was discovered by Poisson and published, together with his probability theory, in 1838 in his work Recherches sur la probabilité des jugements en matières criminelles et matière civile. The work focused on certain random variables N that count, among other things, the number of discrete occurrences (sometimes called "arrivals") that take place during a time‐interval of given length. Poisson Distribution If the expected number of occurrences in this interval is λ, then the probability that there are exactly k occurrences is equal to λ is a positive real number, equal to the expected number of occurrences that occur during the given interval. For instance, if the events occur on average 4 times per minute, and you are interested in the number of events occurring in a 10 minute interval, you would use as your model a Poisson distribution with λ = 10×4 = 40. As a function of k, this is the probability mass function. The Poisson distribution can be derived as a limiting case of the binomial distribution. The Poisson distribution can be applied to systems with a large number of possible events, each of which is rare. A classic example is the nuclear decay of atoms. Siméon Poisson Michel Chasles Michel Floréal Chasles (1793–1880) studied at the École Polytechnique under Poisson. In the War of the Sixth Coalition he was drafted to fight in the defence of Paris in 1814. After the war, he gave up on a career as an engineer or stockbroker in order to pursue his mathematical studies. In 1837 he published his Historical view of the origin and development of methods in geometry, a study of the method of reciprocal polars in projective geometry. The work gained him considerable fame and respect and he was appointed Professor at the École Polytechnique in 1841, then he was awarded a chair at the Sorbonne in 1846. Jakob Steiner had proposed the problem of enumerating the number of conic sections tangent to each of five given conics, and had answered it incorrectly. Chasles developed a theory of characteristics that enabled the correct enumeration of the conics (there are 3264). Michel Chasles He established several important theorems (all called Chasles' theorem). That on solid body kinematics was seminal for understanding their motions, and hence to the development of the theories of dynamics of rigid bodies. In 1865 he was awarded the Copley Medal. As described in A Treasury of Deception, by Michael Farquhar, between 1861 and 1869 Chasles purchased over 27,000 forged letters from Frenchman Vrain‐Denis Lucas. Included in this trove — all apparently written in modern French — were letters from Alexander the Great to Aristotle, from Cleopatra to Julius Caesar (written in French!), and from Mary Magdalene to a revived Lazarus. Chasles' name is one of 72 that appears on the Eiffel Tower. The Gullible Chasles « Ce grand mathématicien collectionnait les documents anciens et fut une victime un peu naïve et complaisante d’un faussaire qui lui vendit des fausses lettres de Pascal prouvant soi‐disant que Pascal avait découvert la gravitation universelle avant Newton. L’histoire de cette fraude scientifique a fait l’objet d’un téléfilm très réussi en 1998, avec Michel Piccoli. A partir de juillet 1867, le mathématicien présenta à l'Académie des sciences une série de lettres inédites prétendument de Pascal, que le faussaire Vrain‐Lucas venait de fabriquer. Elles voulaient établir qu'avant Newton, l'auteur des Pensées avait découvert le principe de l'attraction universelle. Un savant anglais fit observer qu'on y trouvait des mesures astronomiques bien postérieures à la mort de Pascal. Approvisionné une nouvelle fois par Vrain‐Lucas, Chasles montra alors des lettres où Galilée communiquait à Pascal les résultats de ses observations… The Gullible Chasles … Le savant anglais remarqua cette fois que dans une lettre de 1641, Galilée se plaignait de sa mauvaise vue, alors qu'il était complètement aveugle depuis près de quatre ans. Surgit alors une nouvelle lettre, postérieure à la précédente et datée de décembre 1641, dans laquelle un autre savant italien apprenait à Pascal que Galilée, dont la vue n'avait cessé de baisser, avait fini par la perdre entièrement. Ses collègues de l'Institut prirent la chose avec bonne humeur, mais à l'étranger — à Londres en particulier — on fit des gorges chaudes du manque d'esprit critique des scientifiques français. Quant à Chasles, il se montra désespéré de s'être fait ainsi mystifier. D'autant que, comme on l'apprit plus tard, il avait acheté à Vrain‐ Lucas d'autres lettres, d'Alexandre le Grand à Aristote, de Jules César à Vercingétorix, de César à Cléopâtre, toutes rédigées dans un faux vieux français. Chasles légua à sa mort sa collection à l'Institut, y compris les faux fabriqués par Vrain‐Lucas. » Michel Chasles Michel Chasles AB + BC = AC Jean‐Gaston Darboux Jean‐Gaston Darboux (1842‐1917) was a French mathematician who made important contributions to geometry and mathematical analysis. He was a biographer of Henri Poincaré and edited the Selected Works of Joseph Fourier. Darboux received his Ph.D. from ENS in 1866. His thesis, written under the direction of Chasles, was titled Sur les surfaces orthogonales. In 1884, Darboux was elected to the Académie des Sciences. In 1900, he was appointed the Academy's permanent secretary of its Mathematics section. Among his students were Charles‐Emile Picard, Emile Borel and Élie Cartan. In 1902, he was elected to the Royal Society; in 1916, he received the Sylvester Medal from the Society. Jean‐Gaston Darboux Many mathematical objects are named after Darboux: Darboux’s equation, frame, integral, function, net invariants, formula, vector, problem, cubic, transformation, theorem in symplectic geometry, theorem in real analysis (related to Intermediate value theorem), or after Darboux and others: Christoffel‐Darboux identity, Christoffel‐Darboux formula, Euler‐Darboux equation, Euler‐Poisson‐Darboux equation, Darboux‐Goursat problem etc Jean‐Gaston Darboux Charles‐Emile Picard Charles Émile Picard (1856‐1941) was a French mathematician. He was elected the fifteenth member to occupy seat 1 of the Académie Française in 1924. Picard's mathematical papers, textbooks, and many popular writings exhibit an extraordinary range of interests, as well as an impressive mastery of the mathematics of his time. Modern students of complex variables are probably familiar with two of his named theorems. His lesser theorem states that every nonconstant entire function takes every value in the complex plane, with perhaps one exception. His greater theorem states that an analytic function with an essential singularity takes every value infinitely often, with perhaps one exception, in any neighborhood of the singularity. Charles‐Emile Picard Picard also made important contributions in the theory of differential equations, including work on Painlevé transcendents and his introduction of a kind of symmetry group for a linear differential equation, the Picard group. In connection with his work on function theory, he was one of the first mathematicians to use the emerging ideas of algebraic topology. In addition to his path‐ breaking theoretical work, Picard made important contributions to applied mathematics, including the theories of telegraphy and elasticity. His collected papers run to four volumes. Like his contemporary, Henri Poincaré, Picard was much concerned with the training of mathematics, physics, and engineering students. He wrote a classic textbook on analysis, one of the first textbooks on the theory of relativity. Picard's popular writings include biographies of many leading French mathematicians, including his father in law, Charles Hermite. Charles‐Emile Picard Jacques Salomon Hadamard Jacques Salomon Hadamard (1865–1963) was a made major contributions in number theory, complex function theory, differential geometry and partial differential equations. The son of a teacher, Amédée Hadamard, of Jewish descent, and Claire Marie Jeanne Picard, Hadamard attended the Lycée Charlemagne and Lycée Louis‐le‐Grand, where his father taught. In 1884 Hadamard entered the ENS, having been placed first in the entrance examinations both there and at the École Polytechnique. His teachers included Hermite, Darboux and Picard. He obtained his doctorate in 1892 and in the same year was awarded the Grand Prix des Sciences Mathématiques for his prize essay on the Riemann zeta function. Jacques Salomon Hadamard In 1892 Hadamard got married (he had 5 children). The following year he took up a lectureship in the University of Bordeaux, where he proved his celebrated inequality on determinants, which led to the discovery of Hadamard matrices when equality holds. In 1896 he made two important contributions: he proved the prime number theorem, using complex function theory and he was awarded the Bordin Prize of the French Academy of Sciences for his work on geodesics in the differential geometry of surfaces and dynamical systems. In the same year he was appointed Professor of Astronomy and Rational Mechanics in Bordeaux. For his cumulative work, he was awarded the Prix Poncelet in 1898. After the Dreyfus affair, which involved him personally because his wife was related to Dreyfus, Hadamard became politically active and a supporter of Jewish causes though he professed to be an atheist in his religion. Jacques Salomon Hadamard In 1897 he moved to Paris, holding positions at Sorbonne and Collège de France (appointed Professor of Mechanics in 1909). In addition, he was appointed to chairs of analysis at the École Polytechnique in 1912 and at the École Centrale in 1920, succeeding Jordan. In Paris Hadamard concentrated on the problems of mathematical physics, in particular partial differential equations, the calculus of variations and the foundations of functional analysis. He introduced the idea of well‐posed problem and the method of descent in the theory of partial differential equations, culminating in his book on the subject, based on lectures given at Yale in 1922. He was elected to the French Academy of Sciences in 1916, in succession to Poincaré. He was awarded the CNRS Gold medal for lifetime achievements in 1956. His students included Maurice Fréchet, Szolem Mandelbrojt and André Weil. Jacques Salomon Hadamard Szolem Mandelbrojt Szolem Mandelbrojt (1899–1983) was a Jewish‐Polish mathematician. He worked mainly in classical analysis; he was a student of Jacques Hadamard, and became Hadamard's successor as Professor at the Collège de France. He was an early member of the Bourbaki group. In fact his direction was very different, as his publications show, with an interest in Dirichlet series, lacunary series, entire functions and other major topics in complex analysis and harmonic analysis. During World War II he was in Houston, USA at the Rice Institute from 1940, being one of many French scientists helped by the program of Louis Rapkine after the fall of France in June. Benoît Mandelbrot is his nephew, and Jean‐Pierre Kahane one of his students. Jean‐Pierre Kahane Jean Pierre Kahane (born in 1926) is a french mathematician. He attended ENS and obtained his mathematics agrégation in 1949. He then worked for the CNRS from 1949 to 1954, and defended his PhD in 1954; his advisor was Szolem Mandelbrojt. He was assistant professor and professor of mathematics in Montpellier from 1954 to 1961 and a professor from 1961 until his retirement (1994) at Université de Paris‐Sud in Orsay. He was elected corresponding member of the French Academy of Sciences in 1982 and full member in 1998. In 2002 he became commander in the order of the Légion d'Honneur. Jean‐Pierre Kahane Jean‐Louis Krivine Jean‐Louis Krivine Jacques! Demetrios Kydones Jacob Bernoulli Manuel Chrysoloras Johann Bernoulli Guarino da Verona Leonhard Paul Euler Vittorino da Feltre Joseph Lagrange Theodorus Gaza Siméon Poisson Rodolphus Agricola Michel Chasles Alexander Hegius Jean‐Gaston Darboux Erasmus Charles‐Emile Picard Jacob Milich Jacques Salomon Hadamard Erasmus Reinhold Szolem Mandelbrojt Valentin Naboth Jean‐Pierre Kahane Rudolph Snel van Royen Jean‐Louis Krivine Willebrord Snellius Jacques Stern Jacob van Gool Franciscus van Schooten Christiaan Huygens Gottfried Wilhelm Leibniz Jacques’ students with no descendents as yet Jacques’ students with descendents Industry: 32 VeriSign Nagra (2) EADS Cryptolog (2) Clipperton Fidequity HSBC (2) Apple CryptoExperts BNP Paribas SAGEM Gemalto Orange (7) SwissSign Siemens Oberthur Google Irisresearch, Norway. Thales (2) Ingénico (2) plus two unspecified occupations. State Services: 11 CELAR Défense (5) DCSSI (3) DGA Ministère des Affaires Etrangères Full‐Time Researchers : 7 DR CNRS ‐ LRI DR CNRS ‐ Caen DR CNRS – ENS DR INRIA ‐ ENS CR CNRS ‐ LRI CR CNRS ‐ LIX CR CNRS ‐ Caen Full Time Researchers, Abroad: 1 CONICET (CNRS Argentina), Buenos Aires Educators, France : 24 Pr. Caen (2) Pr. UVSQ Pr. Paris II Pr. 3iL Limoges Pr. Paris 7 Pr. UVSQ Pr. Univ. Dauphine Pr. LIF Marseilles MC Paris 6 MC Telecom ParisTech MC ENS MC Paris 8 MC GREYC, Caen (4) MC LIF, Marseilles (2) MC LATP, Marseille MC LINA, Nantes plus two classe prépatoire professors. Educators, Abroad: 5 Pr. EPFL Pr. Morocco Pr. Luxembourg Pr. HES‐SO: Haute école Pr. spécialisée de Suisse occidentale Pr. UCL, London Postdocs and other humanitarian volunteers: 7 Humanitarian mission at Burkina Fasso Post‐doc at Univ. Reims Post‐doc at ENS (2) Post‐doc at Univ. Catholique de Louvain‐la‐Neuve Post‐doc at Univ. Grenoble Post‐doc at LORIA A Variety of Contributions I asked each of the descendents to send me his/her most important scientific contribution. Not all responded but all answers I got were compiled in a « full list », available upon request. As This Presentation Ends I voice all these descendents’ thanks, respect and recognition. Thank you Jacques! Thank you for your contributions to science. Thank you for your contributions to education. Thank you for your mentoring and caring guidance. You helped many become researchers, it is our challenge to live up to this heritage, transmit it and enrich it by writing the book’s next pages! A Small Token of Recognition…